Angular velocity detection circuit, angular velocity detection apparatus, and failure determination system

ABSTRACT

An angular velocity detection circuit is connected to a resonator for making excited vibration on the basis of a drive signal and detects an angular velocity. The angular velocity detection circuit includes: a self-vibration component extraction unit that receives, from the resonator, a detection signal including an angular velocity component based on a Coriolis force and a self-vibration component based on the excited vibration and extracts the self-vibration component from the detection signal; a direct-current conversion unit including an integration unit that integrates an output signal of the self-vibration component extraction unit; and a temperature characteristic compensation unit that compensates for a variation due to a temperature in an output signal of the direct-current conversion unit.

This is a Continuation of application Ser. No. 12/504,126 filed Jul. 16, 2009, which claims the benefit of Japanese Application No. 2008-186137 filed Jul. 17, 2008. The disclosure of the prior applications is hereby incorporated by reference herein in its entirety.

BACKGROUND

1. Technical Field

The present invention relates to an angular velocity detection circuit, an angular velocity detection apparatus, and a failure determination system.

2. Related Art

There have been widely used angular velocity detection apparatuses for detecting an angular velocity using the Coriolis force that works on a resonator. Also, in recent years, there have been developed angular velocity detection apparatuses that are allowed to detect their own failures using a self-vibration component based on excited vibration of a resonator (see JP-A-2000-171257).

The amplitude of a self-vibration component based on excited vibration of a resonator also varies due to the temperature characteristic specific to the resonator. Therefore, it is difficult for related-art angular velocity detection apparatuses to determine whether a variation in the amplitude of a self-vibration component are a variation due to the temperature characteristic or a variation due to a failure, as well as to determine with high accuracy whether there is a failure.

SUMMARY

An advantage of the invention is to provide an angular velocity detection circuit, an angular velocity detection apparatus, and a failure determination system that are allowed to detect a failure of a resonator with higher accuracy.

An angular velocity detection circuit according to a first aspect of the invention is an angular velocity detection circuit that is connected to a resonator for making excited vibration on the basis of a drive signal and detects an angular velocity. The angular velocity detection circuit includes: a self-vibration component extraction unit that receives, from the resonator, a detection signal including an angular velocity component based on a Coriolis force and a self-vibration component based on the excited vibration and extracts the self-vibration component from the detection signal; a direct-current conversion unit including an integration unit that integrates an output signal of the self-vibration component extraction unit; and a temperature characteristic compensation unit that compensates for a variation due to a temperature in an output signal of the direct-current conversion unit.

By adopting the first aspect of the invention, the temperature characteristic compensation unit is provided. Thus, variations due to the temperature characteristic in the magnitude of the self-vibration component based on the excited vibration of the resonator are compensated for. Therefore, variations due to a failure therein are detected with high accuracy. As a result, an angular velocity detection circuit that is allowed to detect a failure in a resonator with high accuracy is realized,

In the angular velocity detection circuit according to the first aspect of the invention, the temperature characteristic compensation unit may make the compensation on the basis of a first-order term of a temperature characteristic of the output signal of the direct-current conversion unit.

The angular velocity detection circuit according to the first aspect of the invention may further include a storage unit storing the first-order term of the temperature characteristic. In this case, the temperature characteristic compensation unit may make the compensation on the basis of the first-order term of the temperature characteristic stored in the storage unit.

The angular velocity detection circuit according to the first aspect of the invention may further include an own failure determination unit that determines whether there is a failure in an angular velocity detection apparatus, on the basis of an output signal of the temperature characteristic compensation unit.

In the angular velocity detection circuit according to the first aspect of the invention, the direct-current conversion unit may include an amplification unit that amplifies a signal, the amplification unit being provided before or after the integration unit.

The angular velocity detection circuit according to the first aspect of the invention may further include an offset addition unit that adds an offset value to a signal, the offset addition unit being provided before or after the temperature characteristic compensation unit.

The offset value may be any values including a positive value, a negative value, and zero.

An angular velocity detection apparatus according to a second aspect of the invention includes: a resonator that makes excited vibration on the basis of a drive signal, obtains a Coriolis force caused by a rotation movement and the excited vibration, and outputs a detection signal including an angular velocity component based on the Coriolis force and an self-vibration component based on the excited vibration; and an angular velocity detection circuit that is connected to the resonator and detects an angular velocity. The angular velocity detection circuit includes: a self-vibration component extraction unit that receives the detection signal and extracts the self-vibration component from the detection signal; a direct-current conversion unit including an integration unit that integrates an output signal of the self-vibration component extraction unit; and a temperature characteristic compensation unit that compensates for a variation due to a temperature in an output signal of the direct-current conversion unit.

A failure determination system according to a third aspect of the invention includes: the angular velocity detection apparatus according to the second aspect of the invention; and an external failure determination unit that receives an output signal of the temperature characteristic compensation unit to determine whether there is a failure in the angular velocity detection apparatus,

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described with reference to the accompanying drawings, wherein like reference numerals represent like elements.

FIG. 1 is a circuit block diagram showing an example of an angular velocity detection apparatus according to an embodiment of the invention.

FIGS. 2A to 2G are timing charts in a case where attention is focused on an angular velocity component of a detection signal.

FIGS. 3A to 3G are timing charts in a case where attention is focused on a self-vibration component of the detection signal.

FIG. 4 is a graph showing an example of the relations between the temperature and the output signal voltages of a direct-current conversion unit and a temperature characteristic compensation unit.

FIG. 5 is a circuit drawing showing an example of the temperature characteristic compensation unit.

FIG. 6 is a circuit block diagram showing an example of an own failure determination unit having multiple failure determination functions.

FIG. 7 is a circuit block diagram showing an example configuration of an angular velocity detection apparatus where an offset addition unit is provided after the temperature characteristic compensation unit.

FIG. 8 is a graph showing an example of the relations between the temperature and the output signal voltages of the direct-current conversion unit, temperature characteristic compensation unit, and offset addition unit.

FIG. 9 is a circuit diagram showing an example of the offset addition unit.

FIGS. 10A and 10B are circuit block diagrams showing an example of a failure determination system according to this embodiment.

FIG. 11 is a plan view showing an example of a resonator.

FIG. 12 is a plan view showing an example of a resonator.

FIG. 13 is a circuit diagram showing an example of a synchronous detector circuit including an offset input unit.

DESCRIPTION OF EXEMPLARY EMBODIMENT

Now, a preferred embodiment of the invention will be described in detail with reference to the accompanying drawings. Note that the embodiment described below does not unduly limit the invention as set forth in the appended claims. Also, not all the configurations described in the embodiment are essential configuration requirements of the invention.

1. Angular Velocity Detection Apparatus

FIG. 1 is a circuit block diagram showing an example of an angular velocity detection apparatus according to this embodiment.

An angular velocity detection apparatus 1 according to this embodiment includes an angular velocity detection circuit 5 and a resonator 10, and the angular velocity detection circuit 5 includes a drive circuit 20 and a detection circuit 30. The drive circuit 20 and detection circuit 30 may be formed on a single substrate.

2. Resonator

The resonator 10 becomes excited and vibrates on the basis of drive signals inputted via drive vibration terminals 13 and 14. When an angular velocity movement works on the resonator while the resonator is excited and vibrates, the resonator obtains the Coriolis force. Then, the resonator 10 outputs a detection signal including an angular velocity component based on the Coriolis force and an excited-vibration component based on the excited vibration. Here, the excited-vibration component is 90° out of phase with the angular velocity component based on the Coriolis force.

Next, an example of the resonator 10 formed of a thin plate made of a piezoelectric material such as a quartz crystal will be described with reference to FIGS. 11 and 12. In the resonator 10, drive resonating arms 11 (driving resonator elements in a broad sense) extend from driving base portions 44 in the Y-axis direction of the quartz crystal. The driving base portions 44 are coupled to a detection base portion 49 via coupling arms 45 extending in the X-axis direction of the quartz crystal. Detection resonating arms 12 (detection resonator elements in a broad sense) extend from the detection base portion 49 in the Y-axis direction.

When a drive signal formed by an alternating voltage or an alternating current is applied between a drive electrode 41 on the side surface of each driving resonating arm 11 and a drive electrode 42 on the upper surface thereof, the drive resonating arms 11 make bending vibration due to a piezoelectric effect as shown by arrows B. Then, the resonator 10 makes rotation movement using the Z axis of the quartz crystal as a rotation axis as shown in FIG. 12 and thus the drive resonating arms 11 obtain the Coriolis force in a direction orthogonal to both the direction of the bending vibration shown by the arrows B and the direction of the Z axis. As a result, the coupling arms 45 vibrate as shown in arrows C. Then, the detection resonating arms 12 make bending vibration as shown by arrows D together with the coupling arms 45 in conjunction with the vibration (arrows C) of the coupling arms 45.

Also, the vibration of the drive resonating arms 11 is transmitted to the drive base portions 44, coupling arms 45, and detection base portion 49, thereby causing leakage vibration in the detection resonating arms 12. While this leakage vibration is bending vibration shown by the arrows D like the vibration based on the Coriolis force, it is 90° out of phase with the vibration based on the Coriolis force.

These different types of bending vibration cause an inverse piezoelectric effect, which in turn causes an alternating voltage or an alternating current between the detection electrode 47 on the side surface of each detection resonating arm and detection electrode 46 on the upper surface thereof. One of the detection electrode 47 and detection electrode 46 is connected to a ground terminal 17 and the other is connected to detection terminals 15 and 16. Thus, detection signals outputted to the detection terminals 15 and 16 include an angular velocity component based on the Coriolis force and a leakage component (self-vibration component) based on the excited vibration due to the drive vibration.

In the configurations shown in FIGS. 11 and 12, the detection base portion 49 is disposed in the center and the detection resonating arms 12 extend from the detection base portion 49 both in +Y-axis direction and in −Y-axis direction so as to bring the resonator into good balance. Also, the coupling arms 45 extend from the detection base portion 49 both in +X-axis direction and in −X-axis direction, and the drive resonating arms 11 extend from the coupling arms both in +Y-axis direction and in −Y-axis direction.

The drive resonating arms 11 each have a wide portion 43 at an end thereof and a weight is attached to the wide portion 43 so that the Coriolis force is increased. Also, these short resonating arms can obtain a desired resonant frequency due to an effect of the weight. Similarly, the detection resonating arms 12 each have a wide portion 48 at an end thereof and a weight is attached to the wide portion 48.

The resonator 10 is not limited to the above-mentioned configuration and may have any configuration as long as it is a resonator for outputting a detection signal including an angular velocity component based on the Coriolis force and a leakage component based on excited vibration. For example, the resonator 10 may have a configuration where drive resonating arms are also used as detection arms or vice versa or may have a configuration where a piezoelectric film is formed on drive resonating arms or detection resonating arms.

3. Angular Velocity Detection Circuit

The angular velocity detection circuit includes the drive circuit 20 and detection circuit 30. The detection resonating arms 12 are provided with the detection terminals 15 and 16 and the ground terminal 17, and the detection terminals 15 and 16 are connected to the detection circuit 30. Opposite-phase detection signals are outputted from the detection terminals 15 and 16.

FIGS. 2A to 2G are timing charts in a case where attention is focused on an angular velocity component of a detection signal at points (A) to (G) in the block diagram shown in FIG. 1. FIGS. 3A to 3G are timing charts in a case where attention is focused on a self-vibration component of the detection signal at points (A) to (G) in the block diagram shown in FIG. 1. The lateral axis represents the time and the longitudinal axis represents the voltage.

The drive circuit 20 outputs a drive signal to drive the resonator 10 and receives a feedback signal from the resonator 10. Thus, the resonator 10 is excited. The detection circuit 30 receives a detection signal from the resonator 10 driven by the drive signal and extracts an angular velocity component based on the Coriolis force from the detection signal.

The drive circuit 20 according to this embodiment includes a current-voltage converter 21, an AC amplifier 22, an automatic gain control circuit 23, and a comparator 24.

When the drive resonating arms 11 vibrate, a current based on a piezoelectric effect is outputted from a drive terminal 14 as a feedback signal and inputted into the current-voltage converter 21. The current-voltage converter 21 outputs an alternating voltage signal having a frequency identical to the vibration frequency of the drive resonating arms 11 (FIG. 2A and FIG. 3A).

The alternating voltage signal outputted from the current-voltage converter 21 is inputted into the AC amplifier 22. The AC amplifier amplifies the inputted alternating voltage signal.

An alternating voltage signal outputted from the AC amplifier 22 is inputted into the automatic gain control circuit 23. The automatic gain control circuit 23 controls the gain so that the amplitude of the inputted alternating voltage signal is kept at a constant value and outputs the gain-controlled, alternating voltage signal to a drive terminal 13. The alternating voltage signal inputted into the drive terminal 13 drives the resonator 10.

Also, the alternating voltage signal amplified by the AC amplifier 22 is inputted into the comparator 24. The comparator 24 outputs, to the detection circuit 30, a square wave voltage signal (FIG. 2B) whose output level is changed on the basis of the result of a comparison between the alternating voltage signal and a reference voltage signal using the center of the amplitude of the alternating voltage signal as a reference voltage.

The detection circuit 30 according to this embodiment includes a detection signal amplification unit 31, an angular velocity component extraction unit 32, and a self-vibration component extraction unit 33.

The detection signal amplification unit 31 includes charge amplifiers 311 and 312, a differential amplifier 313, and an AC amplifier 314.

The charge amplifiers 311 and 312 are connected to the detection terminals 15 and 16, respectively, and receive opposite-phase detection signals. The signals that have undergone charge-voltage conversion in the charge amplifiers 311 and 312 are inputted into the differential amplifier 313. The differential amplifier 313 amplifies the difference between the output signals of the charge amplifier 311 and the charge amplifier 312. An output signal of the differential amplifier 313 is further amplified by the AC amplifier 314. Note that when the charge amplifiers 311 and 312 each perform the amplification, the phases of the respective signals advance 90°.

Incidentally, the detection signals outputted from the detection terminals 15 and 16 each include an angular velocity component based on the Coriolis force that works on the resonator 10 and a self-vibration component (leakage signal component) based on the excited vibration of the resonator 10. The angular velocity component extraction unit 32 extracts an angular velocity component from an output signal of the detection signal amplification unit 31. The self-vibration component extraction unit 33 extracts a self-vibration component from the output signal of the detection signal amplification unit 31.

The angular velocity component extraction unit 32 includes a synchronous detector circuit 321, an AC amplifier 325, an integrator circuit 322, a DC amplifier 323, and an output terminal 324. The synchronous detector circuit 321 extracts an angular velocity component by performing synchronous detection of the output signal of the detection signal amplification unit 31 on the basis of the square wave voltage signal (FIG. 2B) outputted by the comparator 24. The angular velocity component signal extracted by the synchronous detector circuit 321 is amplified by the AC amplifier 325 and integrated by the integrator circuit 322, and is then amplified by the DC amplifier 323 and outputted from the output terminal 324 as a direct-current voltage signal.

The self-vibration component extraction unit 33 includes a self-vibration component extraction unit 331, a direct-current conversion unit 332, and a temperature characteristic compensation unit 333.

The self-vibration component extraction unit 331 includes a phase shifter 334 for leading the phase by 90° and a synchronous detector circuit 335. The self-vibration component extraction unit 331 extracts a self-vibration component from the output signal of the detection signal amplification unit 31 by performing synchronous detection of the output signal on the basis of a signal obtained by leading the phase of the square wave voltage signal (FIG. 2B) outputted by the comparator 24 by 90° using the phase shifter 334.

The direct-current conversion unit 332 includes an integrator circuit 336 functioning as an integration unit that integrates an output signal of the self-vibration component extraction unit 331. The direct-current conversion unit 332 converts an output signal of the self-vibration component extraction unit 331 into a direct-current voltage signal. An AC amplifier 343 is provided before the integrator circuit 336, and a DC amplifier 339 is provided thereafter.

Operations of these circuits will be described with reference to the FIGS. 2A to 2G and FIGS. 3A to 3G. Operations in a case where attention is focused on an angular velocity component of a detection signal will be described with reference to FIGS. 2A to 2G, and operations in a case where attention is focused on a self-vibration component of the detection signal will be described with reference to FIGS. 3A to 3G. In this embodiment, it is assumed that an angular velocity component of a detection signal outputted from the detection terminal 15 is a signal having 90° phase lag from a feedback signal outputted from the drive terminal 14. Also, it is assumed that a self-vibration component of a detection signal outputted from the detection terminal 15 is a signal in phase with a feedback signal outputted from the drive terminal 14.

First, operations in a case where attention is focused on an angular velocity component of a detection signal will be described. An angular velocity component of a detection signal outputted from the detection terminal 15 undergoes charge-voltage conversion in the charge amplifier 311. At this time, the phase leads 90°. Therefore, the signal amplified by the differential amplifier 313 and AC amplifier 314 is in phase with a feedback signal shown in FIG. 2A, as shown in FIG. 2C.

When the output signal of the AC amplifier 314 undergoes synchronous detection in the synchronous detector circuit 321 on the basis of an output signal of the comparator 24 shown in FIG. 2B, an output signal of the synchronous detector circuit 321 takes a full-wave rectified waveform shown in FIG. 2D. By integrating the output signal of the synchronous detector circuit 321 in the integrator circuit 322, the angular velocity component of the detection signal is detected as a direct-current voltage. In this way, the angular velocity component of the detection signal is extracted by the angular velocity component extraction unit 32. Also, by amplifying the signal in the AC amplification circuit provided before the integrator circuit 322 and the DC amplifier 323 provided thereafter, the sensitivity is controlled.

On the other hand, when synchronous detection of an output signal of the AC amplifier 314 is performed in the synchronous detector circuit 335 on the basis of a signal (FIG. 2E) obtained by leading the phase of an output signal of the comparator 24 by 90° using the phase shifter 334, an output signal of the synchronous detector circuit 335 takes a waveform shown in FIG. 2F. By integrating the output signal of the synchronous detector circuit 335 in the integrator circuit 336, the direct-current voltage becomes zero as shown in FIG. 2G. In this way, the angular velocity component of the detection signal is eliminated by the self-vibration component extraction unit 33.

Next, operations in a case where attention is focused on a self-vibration component of a detection signal will be described. A self-vibration component of a detection signal outputted from the detection terminal 15 undergoes charge-voltage conversion in the charge amplifier 311. At this time, the phase leads 90°. Therefore, the signal amplified by the differential amplifier 313 and AC amplifier 314 is a signal having 90° phase lead from a feedback signal shown in FIG. 3A, as shown in FIG. 3C.

When synchronous detection of the output signal of the AC amplifier 314 is performed in the synchronous detector circuit 321 on the basis of an output signal of the comparator 24 shown in FIG. 3B, an output signal of the synchronous detector circuit 321 takes a waveform shown in FIG. 3D. By integrating the output signal of the synchronous detector circuit 321 in the integrator circuit 322, the direct-current voltage becomes zero. In this way, the self-vibration component of the detection signal is eliminated by the angular velocity component extraction unit 32.

On the other hand, when synchronous detection of an output signal of the AC amplifier 314 is performed by the synchronous detector circuit 335 on the basis of a signal obtained by leading the phase of a output signal of the comparator 24 shown in FIG. 3E by 90° using the phase shifter 334, an output signal of the synchronous detector circuit 335 takes a full-wave rectified waveform shown in FIG. 3F. By integrating the output signal of the synchronous detector circuit 335 in the integrator circuit 336, the output signal becomes a direct-current voltage proportional to the crest of a full-wave rectified waveform shown in FIG. 3F, as shown in FIG. 3G. In this way, the self-vibration component of the detection signal is extracted by the self-vibration component extraction unit 33.

Incidentally, when a failure occurs in the resonator 10, for example, when a foreign substance is stuck on the resonator 10 or when the resonator 10 is broken, the magnitude of the self-vibration component based on excited vibration of the resonator 10 varies. Therefore, by extracting a self-vibration component of a detection signal in the self-vibration component extraction unit 33 to monitor the magnitude of the self-vibration component of the detection signal inside or outside the resonator 10, it is determined whether there is a failure in the resonator 10. For example, when the self-vibration component of the detection signal exceeds the upper limit reference value or falls below the lower limit reference value, it may be determined that there is a failure in the resonator 10.

However, the magnitude of the self-vibration component based on the excited vibration of the resonator 10 also varies due to the temperature characteristic specific to the resonator. Therefore, it is difficult for related-art angular velocity detection apparatuses to determine whether variations in the magnitude of the self-vibration component are variations due to the temperature characteristic or variations due to a failure, as well as to determine with high accuracy whether there is a failure.

For this reason, the angular velocity detection circuit 5 according to this embodiment includes the temperature characteristic compensation unit 333. The temperature characteristic compensation unit 333 compensates for a variation due to the temperature in an output signal of the direct-current conversion unit 332. For example, the temperature characteristic compensation unit 333 compensates for a variation due to the temperature in the amplitude of an output signal of the direct-current conversion unit 332 so that the amplitude is kept constant. Thus, the variation due to the temperature in the output signal of the direct-current conversion unit 332 is compensated for and a variation due to a failure is detected with high accuracy. As a result, an angular velocity detection circuit that is allowed to detect a failure of a resonator with increased accuracy is realized.

FIG. 4 is a graph showing examples of the relations between the temperature and the output signal voltages of the direct-current conversion unit 332 and temperature characteristic compensation unit 333. The lateral axis represents the temperature and the longitudinal axis represents the output signal voltage.

As shown by a solid line 1001 in FIG. 4, the output signal voltage of the direct-current conversion unit 332 varies with the temperature. The temperature characteristic compensation unit 333 compensates for the variations due to the temperature in the output signal voltage, for example, in directions of outline arrows shown in FIG. 4 so that the output signal voltage is kept constant as shown by a two-dot broken line in FIG. 4, and outputs the resultant signal. FIG. 4 shows an example where variations in the output signal voltage are compensated for using the output signal voltage at 25° C. as the reference.

Also, the inventor found that the variations due to the temperature in the output signal of the direct-current conversion unit 332 can be approximated by a first-order slope. Therefore, the temperature characteristic compensation unit 333 may be configured so that the variations due to the temperature in the output signal of the direct-current conversion unit 332 are compensated for on the basis of the first-order term of the temperature characteristic of the output signal.

Also, the angular velocity detection circuit 5 may include a storage unit 337 for storing the first-order term of the temperature characteristic and the temperature characteristic compensation unit 333 may compensate for the variations due to the temperature in the output signal of the direct-current conversion unit 332 on the basis of the first-order term of the temperature characteristic stored in the storage unit 337. The storage unit 337 may be formed, for example, by a non-volatile memory such as an EEPROM (electrically erasable and programmable read only memory). Thus, for example, the first-order term of the temperature characteristic that allows the output voltage of the temperature characteristic compensation unit 333 measured in the step of inspecting the angular velocity detection apparatus 1 to become approximately a constant value without varying due to the temperature is written into the storage unit 337. Therefore, even if the temperature characteristic varies among resonators, proper temperature characteristic compensation can be performed.

FIG. 5 is a circuit drawing showing an example of the temperature characteristic compensation unit 333 applicable to the angular velocity detection circuit 5 according to this embodiment. The temperature characteristic compensation unit 333 shown in FIG. 5 includes a calculation amplifier 401, a control circuit 402, resistances 403 and 404, and a variable resistance 405.

An output signal of the direct-current conversion unit 332 is inputted into a non-inverting input terminal of the calculation amplifier 401 via the resistance 403. The control circuit 402 controls the resistance value of the variable resistance 405 on the basis of the first-order term of the temperature characteristic stored in the storage unit 337 and the temperature detected by a temperature sensor 406. The calculation amplifier 401 amplifies the difference between the signal inputted into the non-inverting input terminal and a potential inputted into an inverting input terminal thereof and outputs the resultant voltage as an output voltage Vout1. The output voltage Vout1 is also fed back to the inverting input terminal of the calculation amplifier 401 via the resistance 404.

A gain A of the calculation amplifier 401 is represented by A=1+R5/R4, where R4 is the resistance value of the resistance 404 and R5 is the resistance value of the variable resistance 405. Therefore, by controlling the resistance value R5 of the variable resistance 405, the gain of the calculation amplifier 401 is controlled.

As seen above, if the temperature characteristic compensation unit 333 is configured as shown in FIG. 5, the output voltage Vout1 is kept constant without varying due to the temperature by properly setting the first-order term of the temperature characteristic stored in the storage unit 337.

The angular velocity detection circuit 5 according to this embodiment may further include an own failure determination unit 338 for determining whether there is a failure in the angular velocity detection apparatus 1, on the basis of the output signal Vout1 of the temperature characteristic compensation unit 333. If the output signal Vout1 from the temperature characteristic compensation unit 333 exceeds the upper limit reference value or falls below the lower limit reference value, the own failure determination unit 338 determines that there is a failure in the resonator 10 and outputs an output signal based on the determination result. In the block diagram shown in FIG. 1, an output signal is outputted from the angular velocity detection circuit 5 via an output terminal 341. By incorporating the own failure determination unit 338 into the angular velocity detection circuit 5, the angular velocity detection apparatus 1 itself is allowed to determine whether there is a failure in the resonator 10.

The own failure determination unit 338 may have failure additional determination functions using other failure determination signals. FIG. 6 is a circuit block diagram showing an example of the own failure determination unit 338 having multiple failure determination functions. In an example shown in FIG. 6, the own failure determination unit 338 receives a drive circuit diagnosis determination signal used when determining whether there is a failure in the drive circuit 20 and a detection circuit diagnosis determination signal used when determining whether there is a failure in the detection circuit 30 in addition to the output signal Vout1 from the temperature characteristic compensation unit 333 used when determining whether there is a failure in the resonator 10.

The own failure determination unit 338 shown in FIG. 6 includes failure determination circuits 501 to 503 and an OR circuit 504. When any of the failure determination circuits 501 to 503 determines that there is a failure, on the basis of an input signal thereof, the failure determination circuit outputs a high-level output signal. When the failure determination circuits 501 to 503 each determines that there is no failure, they output a low-level output signal.

When the output signal Vout1 from the self-vibration component extraction unit 33 exceeds the upper limit reference value or falls below the lower limit reference value, the failure determination circuit 501 determines that there is a failure in the resonator 10 and outputs an output signal based on the determination result, to the OR circuit 504. When the drive circuit diagnosis determination signal exceeds the upper limit reference value or falls below the lower limit reference value, the failure determination circuit 502 determines that there is a failure in the drive circuit 20 and outputs an output signal based on the determination result, to the OR circuit 504. When the detection circuit diagnosis determination signal exceeds the upper limit reference value or falls below the lower limit reference value, the failure determination circuit 503 determines that there is a failure in the detection circuit 30 and outputs an output signal based on the determination result, to the OR circuit 504.

When the OR circuit 504 receives a high-level output signal of any of the failure determination circuits 501 to 503, it outputs a high-level output signal Vout2. When the OR circuit 504 receives a low-level output signal of any of the failure determination circuits 501 to 503, it outputs a low-level output signal Vout2.

As seen above, if the own failure determination unit 338 is configured as shown in the block diagram of FIG. 6, the own failure determination unit 338 determines whether there is a failure anywhere of the angular velocity detection apparatus 1 and outputs the determination result as the output voltage Vout2.

In the direct-current conversion unit 332 of the angular velocity detection circuit 5 according to this embodiment, the AC amplifier 343 provided before the integrator circuit 336 functioning as an integration unit or the DC amplifier 339 provided thereafter may include an amplification unit that amplifies or attenuates a signal at a desired magnification. In the block diagram shown in FIG. 1, the DC amplifier 339 provided after the integrator circuit 336 functions as that amplification unit.

The magnitude of a self-vibration component based on excited vibration of the resonator 10 varies with the failure mode of the resonator 10. For example, a variation in a self-vibration component based on excited vibration of the resonator 10 at the time when the resonator 10 is broken is larger than a variation in a self-vibration component based on excited-vibration of the resonator 10 at the time when a foreign substance is stuck on the resonator 10.

If the AC amplifier 343 is provided before the integrator circuit 336 or the DC amplifier 339 is provided thereafter, the output sensitivity of the direct-current conversion unit 332 is changed by changing the gain of the DC amplifier 339. Therefore, a failure determination corresponding to a failure mode desired to be detected is made by setting the gain of the DC amplifier 339 in accordance with the failure mode.

Also, a gain control circuit for controlling the gain of the DC amplifier 339 may be provided as a temperature characteristic compensation unit. In this case, the dependence of an output of the DC amplifier 339 on the temperature is reduced.

The angular velocity detection circuit 5 according to this embodiment may include an output terminal 340 for outputting the output signal Vout1 of the temperature characteristic compensation unit 333. By outputting the output signal Vout1 of the temperature characteristic compensation unit 333 from the angular velocity detection circuit 5, a more detailed failure determination can be made outside the angular velocity detection apparatus 1. For example, if a complicated calculation process that cannot be performed inside the angular velocity detection apparatus 1 due to limitations such as the size of the angular velocity detection apparatus 1 is performed using a microcomputer or the like provided outside the angular velocity detection apparatus 1, a more detailed failure determination can be made.

Also, the output terminal 340 may be used to measure the output voltage of the temperature characteristic compensation unit 333 in the step of inspecting the angular velocity detection apparatus 1.

Modification

In the above-mentioned configuration of the angular velocity detection apparatus 1, an offset addition unit 342 for adding an offset value to a signal may be additionally provided before or after the temperature characteristic compensation unit 333. FIG. 7 is a circuit block diagram showing an example configuration of an angular velocity detection apparatus 2 according to a modification of this embodiment, where the offset addition unit 342 is provided after the temperature characteristic compensation unit 333. Same elements as those of the angular velocity detection apparatus 1 described with reference to FIG. 1 are assigned same reference numerals and will not be described in detail.

The amplitude of a self-vibration component based on excited-vibration varies among resonators. Therefore, it is difficult for related-art angular velocity detection apparatuses to make a failure determination with high accuracy unless failure determination conditions are changed in accordance with a resonator included therein.

An angular velocity detection circuit 6 according to this modification includes the offset addition unit 342. The offset addition unit 342 adds a desired offset value to an output signal of the temperature characteristic compensation unit 333.

FIG. 8 is a graph showing an example of the relations between the temperature and the output signal voltages of the direct-current conversion unit 332, temperature characteristic compensation unit 333, and offset addition unit 342. The lateral axis represents the temperature and the longitudinal axis represents the output signal voltage.

As shown by a solid line 2001 in FIG. 8, the magnitude of the output signal voltage of the direct-current conversion unit 332 varies with the temperature. As shown by a two-dot broken line in FIG. 4, the temperature characteristic compensation unit 333 compensates for variations due to the temperature in the output signal voltage, for example, in directions of outline arrows shown in FIG. 8 so that the output signal voltage is kept constant, and outputs the resultant signal. FIG. 8 shows an example where variations in the output signal voltage are compensated for using the output signal voltage at 25 degrees as the reference.

The offset addition unit 342 adds an offset value for making an output voltage of the offset addition unit 342 a desired value, to an output signal of the temperature characteristic compensation unit 333 and outputs the resultant signal. For example, by adding offset values in a direction shown by a black arrow in FIG. 8, the output signal voltage of the offset addition unit 342 is set to a desired value, as shown by a one-dot broken line 2003.

Thus, the variations due to the temperature in the magnitude of the self-vibration component based on excited-vibration component of the resonator 10 are compensated for, and variations among resonators in the self-vibration component based on excited vibration are compensated for so that the magnitudes of output voltages are matched. As a result, an angular velocity detection apparatus that is allowed to detect a failure of a resonator with further increased accuracy without having to change failure determination conditions for each angular velocity detection apparatus is realized.

Also, the angular velocity detection apparatus 2 may include a storage unit that stores an offset value and the offset addition unit 342 may add an offset value stored in the storage unit 337, to an output signal of the temperature characteristic compensation unit 333. Also, the role of this storage unit may be played by the storage unit 337 for storing the first-order term of the temperature characteristic to be used by the temperature characteristic compensation unit 333. Thus, by measuring the output voltage of the offset addition unit 342 in the step of inspecting the angular velocity detection apparatus 2 and then writing an offset value for making this output voltage a desired value into the storage unit 337, variations among resonators in the magnitude of a self-vibration component based on excited vibration are compensated for so that the magnitudes of output voltages are matched.

Also, a gain control circuit for controlling the gain of the DC amplifier 339 may be provided as a temperature characteristic compensation unit. In this case, the dependence of an output of the DC amplifier 339 on the temperature is reduced.

FIG. 9 is a circuit diagram showing an example of the offset addition unit 342 applicable to the angular velocity detection apparatus 2 according to this modification. The offset addition unit 342 shown in FIG. 9 includes a calculation amplifier 601, a D/A converter 602, and resistances 603 to 605.

An output signal of the temperature characteristic compensation unit 333 is inputted into a non-inverting input terminal of the calculation amplifier 601 via the resistance 603. The D/A converter 602 outputs a voltage signal on the basis of an offset value stored in the storage unit 337. The voltage signal outputted by the D/A converter 602 is inputted into an inverting input terminal of the calculation amplifier 601 via the resistance 604. The calculation amplifier 601 amplifies the difference between the signal inputted into the non-inverting input terminal and the signal inputted into the inverting input terminal and outputs the resultant voltage as an output voltage Vout3. Also, the output voltage Vout3 is fed back to the inverting input terminal of the calculation amplifier 601 via the resistance 605.

As seen above, if the offset addition unit 342 is configured as shown in FIG. 9, the output voltage Vout3 is set to a desired value by properly setting an offset value stored in the storage unit 337.

Also, a synchronous detector circuit including an offset input unit that adds an offset value to an output signal of the synchronous detector circuit 335 (self-vibration extraction unit 331) as shown in FIG. 13 may be used as the synchronous detector circuit 335. In this case, a synchronized detection signal (C) is branched into two signals. One of the two signals is inputted into a switch 359 as a non-inverted signal without being inverted; the other is inverted by an inverting amplifier 357 and inputted into a switch 358. By alternately closing the switch 358 and switch 359 using a reference signal, a non-inverted signal and an inverted signal are alternately outputted. Thus, a synchronous detection signal (F) is outputted. Therefore, an offset signal is superimposed on the synchronizing detection signal (F) at the timing when the switches 358 and 359 select and output an inverted signal that is a synchronized signal; no offset signal is superimposed on the synchronizing detection signal (F) at the timing when the switches 358 and 359 select and output a non-inverted signal that is a synchronized signal. In this way, the superimposition and non-superimposition of an offset signal is repeated. Subsequently, the offset signal is smoothed by the integrator circuit 336 so that a given level of offset value is obtained. Also, an offset signal may be superimposed on a non-inverted signal.

Similarly, a synchronous detection circuit including an offset signal input unit may be used as the synchronous detector circuit 321 of the angular velocity component extraction unit 32.

4. Failure Determination System

FIGS. 10A and 10B are circuit block diagrams showing an example of a failure determination system according to this embodiment.

A failure determination system 3 according to this embodiment shown in FIG. 10A includes the angular velocity detection apparatus 1. Since the configuration and operations of the angular velocity detection apparatus 1 are as described above with reference to FIGS. 1 to 6, same elements are assigned same reference numerals and will not be described in detail.

The failure determination system 3 according to this embodiment includes an external failure determination unit 700 for determining whether there is a failure in the angular velocity detection apparatus 1, on the basis of the output signal Vout1 from the output terminal 340 of the angular velocity detection apparatus 1. The external failure determination unit 700 may be formed, for example, by a microcomputer.

For example, when the output signal Vout1 from the angular velocity detection apparatus 1 exceeds the upper limit reference value or falls below the lower limit reference value, the external failure determination unit 700 may determine that there is a failure in the resonator 10 of the angular velocity detection apparatus 1. Also, for example, the external failure determination unit 700 may makes a more detailed failure determination by performing a complicated calculation process that cannot be performed inside the angular velocity detection apparatus 1 due to limitations such as the size of the angular velocity detection apparatus 1.

Modification

The angular velocity detection apparatus 1 of the above-mentioned failure determination system 3 may be replaced with the angular velocity detection apparatus 2. A failure determination system 4 according to a modification of this embodiment, shown in FIG. 10B, includes the angular velocity detection apparatus 2. Since the configuration and operations of the angular velocity detection apparatus 2 are as described above with reference to FIGS. 1 to 9, same elements are assigned same reference numerals and will not be described in detail.

In the failure determination system 4 according to this modification, an external failure determination unit determines whether there is a failure in the angular velocity detection apparatus 2, on the basis of the output voltage Vout3 from the output terminal 340 of the angular velocity detection apparatus 2.

Since the angular velocity detection apparatus 2 is used instead of the angular velocity detection apparatus 1, the failure determination system 4 is allowed to make a failure determination with higher accuracy.

The invention is not limited to the above-mentioned embodiment and modifications thereof and various other modifications can be made without departing from the spirit and scope of the invention.

The invention includes configurations (for example, configurations identical in function, method, and result and configurations identical in object and advantage) substantially identical to the configuration in the above-mentioned embodiment. Also, the invention includes configurations where non-substantial portions of the elements described in the above-mentioned embodiment are replaced. Also, the invention includes configurations having advantages identical to those of the configuration described in the above-mentioned embodiment and configurations that can achieve the object identical to that of the configuration described in the above-mentioned embodiment. Also, the invention includes configurations where known technology is added to the configuration described in the above-mentioned embodiment. 

What is claimed is:
 1. A circuit for use in a physical quantity detection device, comprising: a self-vibration component extraction unit that receives, from a resonator, a signal that includes (i) a first component according to a magnitude of a physical quantity, and (ii) a second component based on an excited vibration, the self-vibration component extraction unit extracting the second component from the signal; and a temperature characteristic compensation unit that compensates for variations due to a temperature in an output signal of the self-vibration component extraction unit.
 2. The circuit for use in a physical quantity detection device according to claim 1, the resonator comprising: a coupling arm that extends from a detection base portion; a driving resonator element that extends from a driving base portion, the driving base portion arranged on the coupling arm and in a direction that intersects the direction in which the coupling arm extends; and a detection resonator element that extends from the detection base portion in a direction that intersects the direction in which the coupling arm extends.
 3. The circuit for use in a physical quantity detection device according to claim 1, wherein the temperature characteristic compensation unit compensates for variations due to the temperature in the output signal of the self-vibration component extraction unit on the basis of a first-order term of a temperature characteristic in the output signal of the self-vibration component extraction unit.
 4. The circuit for use in a physical quantity detection device according to claim 3, further comprising: a storage unit that stores the first-order term of the temperature characteristic, wherein the temperature characteristic compensation unit compensates for variations due to the temperature in the output signal of the self-vibration component extraction unit based on the first-order term of the temperature characteristic stored in the storage unit.
 5. The circuit for use in a physical quantity detection device according to claim 1, further comprising: a determination unit that monitors and determines the output signal of the temperature characteristic compensation unit.
 6. The circuit for use in a physical quantity detection device according to claim 1, further comprising: an amplification unit that amplifies the signal, the amplification unit provided before or after the self-vibration component extraction unit.
 7. The circuit for use in a physical quantity detection device according to claim 1, further comprising: an offset addition unit that adds an offset value to the signal, the offset addition unit provided before or after the temperature characteristic compensation unit.
 8. A physical quantity detection device, comprising: a resonator that generates a signal having (i) a first component according to a magnitude of a physical quantity, and (ii) a second component based on an excited signal; a self-vibration component extraction unit that receives the signal and extracts the second component from the signal; and a temperature characteristic compensation unit that compensates for variations due to a temperature in an output signal of the self-vibration component extraction unit.
 9. The physical quantity detection device according to claim 8, the resonator comprising: a coupling arm extending from a detection base portion; a driving resonator element that extends from a driving base portion, the driving base portion arranged on the coupling arm and in a direction that intersects the direction in which the coupling arm extends; and a detection resonator element that extends from the detection base portion in a direction that intersects the direction in which the coupling arm extends.
 10. The circuit for use in a physical quantity detection device according to claim 8, wherein the temperature characteristic compensation unit compensates for a variation due to the temperature in the output signal of the self-vibration component extraction unit on the basis of a first-order term of a temperature characteristic in the output signal of the self-vibration component extraction unit.
 11. The physical quantity detection device according to claim 10, further comprising: a storage unit that stores the first-order term of the temperature characteristic, wherein the temperature characteristic compensation unit compensates for variations due to the temperature in the output signal of the self-vibration component extraction unit based on the first-order term of the temperature characteristic stored in the storage unit.
 12. The physical quantity detection device according to claim 8, further comprising: a determination unit that monitors and determines the output signal of the temperature characteristic compensation unit.
 13. The physical quantity detection device according to claim 8, further comprising: an amplification unit that amplifies the signal, the amplification unit provided before or after the self-vibration component extraction unit.
 14. The physical quantity detection device according to claim 8, further comprising: an offset addition unit that adds an offset value to the signal, the offset addition unit provided before or after the temperature characteristic compensation unit.
 15. A failure determination system, comprising: the physical quantity detection device according to claim 8, and an external failure determination unit that (i) receives an output signal from the temperature characteristic compensation unit, and (ii) determines whether there is a failure in the physical quantity detection device. 